ClinVar Genomic variation as it relates to human health
NM_005055.5(RAPSN):c.264C>A (p.Asn88Lys)
The aggregate germline classification for this variant, typically for a monogenic or Mendelian disorder as in the ACMG/AMP guidelines, or for response to a drug. This value is calculated by NCBI based on data from submitters. Read our rules for calculating the aggregate classification.
Stars represent the aggregate review status, or the level of review supporting the aggregate germline classification for this VCV record. This value is calculated by NCBI based on data from submitters. Read our rules for calculating the review status. The number of submissions which contribute to this review status is shown in parentheses.
No data submitted for somatic clinical impact
No data submitted for oncogenicity
Variant Details
- Identifiers
-
NM_005055.5(RAPSN):c.264C>A (p.Asn88Lys)
Variation ID: 8046 Accession: VCV000008046.79
- Type and length
-
single nucleotide variant, 1 bp
- Location
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Cytogenetic: 11p11.2 11: 47448079 (GRCh38) [ NCBI UCSC ] 11: 47469631 (GRCh37) [ NCBI UCSC ]
- Timeline in ClinVar
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First in ClinVar Help The date this variant first appeared in ClinVar with each type of classification.
Last submission Help The date of the most recent submission for each type of classification for this variant.
Last evaluated Help The most recent date that a submitter evaluated this variant for each type of classification.
Germline Apr 30, 2015 Nov 24, 2024 Mar 30, 2024 - HGVS
-
Nucleotide Protein Molecular
consequenceNM_005055.5:c.264C>A MANE Select Help Transcripts from the Matched Annotation from the NCBI and EMBL-EBI (MANE) collaboration.
NP_005046.2:p.Asn88Lys missense NM_032645.5:c.264C>A NP_116034.2:p.Asn88Lys missense NC_000011.10:g.47448079G>T NC_000011.9:g.47469631G>T NG_008312.1:g.6100C>A Q13702:p.Asn88Lys - Protein change
- N88K
- Other names
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p.N88K
- Canonical SPDI
- NC_000011.10:47448078:G:T
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Functional
consequence HelpThe effect of the variant on RNA or protein function, based on experimental evidence from submitters.
- -
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Global minor allele
frequency (GMAF) HelpThe global minor allele frequency calculated by the 1000 Genomes Project. The minor allele at this location is indicated in parentheses and may be different from the allele represented by this VCV record.
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0.00120 (T)
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Allele frequency
Help
The frequency of the allele represented by this VCV record.
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1000 Genomes Project 0.00120
1000 Genomes Project 30x 0.00141
The Genome Aggregation Database (gnomAD) 0.00149
The Genome Aggregation Database (gnomAD), exomes 0.00156
Exome Aggregation Consortium (ExAC) 0.00159
Trans-Omics for Precision Medicine (TOPMed) 0.00160
- Links
Genes
Gene | OMIM | ClinGen Gene Dosage Sensitivity Curation |
Variation Viewer
Help
Links to Variation Viewer, a genome browser to view variation data from NCBI databases. |
Related variants | ||
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HI score
Help
The haploinsufficiency score for the gene, curated by ClinGen’s Dosage Sensitivity Curation task team. |
TS score
Help
The triplosensitivity score for the gene, curated by ClinGen’s Dosage Sensitivity Curation task team. |
Within gene
Help
The number of variants in ClinVar that are contained within this gene, with a link to view the list of variants. |
All
Help
The number of variants in ClinVar for this gene, including smaller variants within the gene and larger CNVs that overlap or fully contain the gene. |
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RAPSN | - | - |
GRCh38 GRCh37 |
679 | 693 |
Conditions - Germline
Condition
Help
The condition for this variant-condition (RCV) record in ClinVar. |
Classification
Help
The aggregate germline classification for this variant-condition (RCV) record in ClinVar. The number of submissions that contribute to this aggregate classification is shown in parentheses. (# of submissions) |
Review status
Help
The aggregate review status for this variant-condition (RCV) record in ClinVar. This value is calculated by NCBI based on data from submitters. Read our rules for calculating the review status. |
Last evaluated
Help
The most recent date that a submitter evaluated this variant for the condition. |
Variation/condition record
Help
The RCV accession number, with most recent version number, for the variant-condition record, with a link to the RCV web page. |
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Pathogenic (2) |
criteria provided, multiple submitters, no conflicts
|
Jan 17, 2014 | RCV000008512.18 | |
Pathogenic/Likely pathogenic (11) |
criteria provided, multiple submitters, no conflicts
|
Mar 29, 2023 | RCV000170316.27 | |
Pathogenic (13) |
criteria provided, multiple submitters, no conflicts
|
Feb 1, 2024 | RCV000224062.53 | |
Pathogenic (3) |
criteria provided, single submitter
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Feb 1, 2022 | RCV000235028.12 | |
Likely pathogenic (1) |
criteria provided, single submitter
|
Mar 5, 2018 | RCV000286918.20 | |
Likely pathogenic (1) |
criteria provided, single submitter
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May 5, 2015 | RCV000414829.10 | |
Pathogenic (4) |
criteria provided, multiple submitters, no conflicts
|
Jan 31, 2024 | RCV000477955.22 | |
Pathogenic (1) |
criteria provided, single submitter
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Dec 13, 2021 | RCV002512909.9 | |
Pathogenic (1) |
criteria provided, single submitter
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Mar 30, 2024 | RCV003466838.2 | |
Pathogenic (1) |
no assertion criteria provided
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Jun 21, 2024 | RCV004732539.1 |
Submissions - Germline
Classification
Help
The submitted germline classification for each SCV record. (Last evaluated) |
Review status
Help
Stars represent the review status, or the level of review supporting the submitted (SCV) record. This value is calculated by NCBI based on data from the submitter. Read our rules for calculating the review status. This column also includes a link to the submitter’s assertion criteria if provided, and the collection method. (Assertion criteria) |
Condition
Help
The condition for the classification, provided by the submitter for this submitted (SCV) record. This column also includes the affected status and allele origin of individuals observed with this variant. |
Submitter
Help
The submitting organization for this submitted (SCV) record. This column also includes the SCV accession and version number, the date this SCV first appeared in ClinVar, and the date that this SCV was last updated in ClinVar. |
More information
Help
This column includes more information supporting the classification, including citations, the comment on classification, and detailed evidence provided as observations of the variant by the submitter. |
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Pathogenic
(Jan 17, 2014)
|
criteria provided, single submitter
Method: clinical testing
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Myasthenic syndrome, congenital, associated with acetylcholine receptor deficiency
(Autosomal recessive inheritance)
Affected status: not provided
Allele origin:
germline
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Laboratory for Molecular Medicine, Mass General Brigham Personalized Medicine
Study: CSER-MedSeq
Accession: SCV000221210.2 First in ClinVar: Apr 01, 2015 Last updated: Jun 28, 2015 |
Comment:
The Asn88Lys variant in RAPSN has been previously identified in many individuals with congenital myasthenic syndrome and has been shown to segregate with disease in … (more)
The Asn88Lys variant in RAPSN has been previously identified in many individuals with congenital myasthenic syndrome and has been shown to segregate with disease in several affected family members (Ohno 2002, Dunne 2003, Richard 2003, Muller 2003, Banwell 2004, Yasaki 2004, Muller 2004, Ioos 2004, Cossins 2006, Skeie 2006, Milone 2009, Brugoni 2010, Bell 2011, Alseth 2011). This variant has been identified in 0.01% (13/8596) of European American chromosomes by the NHLBI Exome Sequencing Project (http://evs.gs.washington.edu/EVS/; dbSNP rs104894299). Although this variant has been seen in the general population, its frequency is low enough to be consistent with a recessive carrier frequency. Functional studies indicate the Asn88Lys variant results in reduced co-localization with the acetylcholine receptor (AChR) (Cossins 2006). In summary, this variant meets our criteria to be classified as pathogenic (http://pcpgm.partners.org/LMM) based upon segregation studies and functional evidence. (less)
Number of individuals with the variant: 1
|
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Pathogenic
(Aug 22, 2014)
|
criteria provided, single submitter
Method: clinical testing
|
not provided
Affected status: not provided
Allele origin:
germline
|
Center for Pediatric Genomic Medicine, Children's Mercy Hospital and Clinics
Accession: SCV000281522.1
First in ClinVar: Jun 08, 2016 Last updated: Jun 08, 2016 |
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Likely pathogenic
(May 05, 2015)
|
criteria provided, single submitter
Method: clinical testing
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Myopathy
Affected status: yes
Allele origin:
unknown
|
Centre for Mendelian Genomics, University Medical Centre Ljubljana
Accession: SCV000492841.1
First in ClinVar: Jan 13, 2017 Last updated: Jan 13, 2017 |
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Pathogenic
(May 18, 2017)
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criteria provided, single submitter
Method: clinical testing
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Fetal akinesia deformation sequence 1
Congenital myasthenic syndrome 11
Affected status: unknown
Allele origin:
unknown
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Fulgent Genetics, Fulgent Genetics
Accession: SCV000611311.1
First in ClinVar: Apr 23, 2017 Last updated: Apr 23, 2017 |
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Pathogenic
(Jun 19, 2018)
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criteria provided, single submitter
Method: clinical testing
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not provided
Affected status: unknown
Allele origin:
germline
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Eurofins Ntd Llc (ga)
Accession: SCV000227353.5
First in ClinVar: Jun 28, 2015 Last updated: Dec 15, 2018 |
Number of individuals with the variant: 8
Sex: mixed
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Pathogenic
(Jan 01, 2016)
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criteria provided, single submitter
Method: clinical testing
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Congenital myasthenic syndrome 11
Affected status: yes
Allele origin:
unknown
|
Centre for Mendelian Genomics, University Medical Centre Ljubljana
Accession: SCV001368826.2
First in ClinVar: Jul 06, 2020 Last updated: Dec 12, 2020 |
Comment:
This variant was classified as: Pathogenic. The following ACMG criteria were applied in classifying this variant: PS3,PM2,PS1,PP3.
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Pathogenic
(Jul 28, 2022)
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criteria provided, single submitter
Method: clinical testing
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Congenital myasthenic syndrome 11
Affected status: yes
Allele origin:
germline
|
MGZ Medical Genetics Center
Accession: SCV002581622.1
First in ClinVar: Oct 15, 2022 Last updated: Oct 15, 2022
Comment:
ACMG criteria applied: PS3, PM3_STR, PP1, PP3
|
Number of individuals with the variant: 2
Sex: male
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Pathogenic
(Feb 02, 2021)
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criteria provided, single submitter
Method: clinical testing
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Congenital myasthenic syndrome 11
(Autosomal recessive inheritance)
Affected status: yes
Allele origin:
germline
|
Genetics and Molecular Pathology, SA Pathology
Additional submitter:
Shariant Australia, Australian Genomics
Accession: SCV002556391.2
First in ClinVar: Aug 08, 2022 Last updated: Dec 17, 2022 |
Comment:
The RAPSN c.264C>A variant is classified as a PATHOGENIC VARIANT (PS3, PS4, PP1, PP3, PP5) This variant is a single nucleotide change from a cytosine … (more)
The RAPSN c.264C>A variant is classified as a PATHOGENIC VARIANT (PS3, PS4, PP1, PP3, PP5) This variant is a single nucleotide change from a cytosine to an adenine at position 264 which is predicted to change the Asparagine at position 88 in the protein to Lysine. The variant is in exon 2 and is located in protein domain: tetratricopeptide repeat, of the RAPSN gene. This variant is a common pathogenic variant in the RAPSN gene causing congenital myasthenic syndrome (CMSs), and has been reported in many individuals with CMSs in both the homozygous or compound heterozygous state (PS4). Further, this variant has also been shown to segregate with disease in multiples families with CMSs (PP1) (PMID: 12796535, 16945936, 14504330). In vitro functional studies have demonstrated that this variant reduced the recruitment of the acetylcholine receptor (AChR) to rapsyn clusters, as well as impaired postsynaptic morphological development (PMID: 11791205, 16945936) (PS3). The variant is in dbSNP (rs104894299) and has been reported in population databases (gnomAD: 429/282254, 0 homozygote). The variant has been reported in ClinVar (Variation ID: 8046) and HGMD (Accession ID: CM020758) as pathogenic (PP5). Computational predictions support a deleterious effect on the gene or gene product (PP3). (less)
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Pathogenic
(Mar 29, 2023)
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criteria provided, single submitter
Method: clinical testing
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Congenital myasthenic syndrome 11
(Autosomal recessive inheritance)
Affected status: yes
Allele origin:
maternal
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Equipe Genetique des Anomalies du Developpement, Université de Bourgogne
Accession: SCV003920984.1
First in ClinVar: May 06, 2023 Last updated: May 06, 2023 |
Comment:
This variant was observed in heterozygosity with variant c.123del
Method: Exome sequencing
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Pathogenic
(Oct 26, 2023)
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criteria provided, single submitter
Method: clinical testing
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not provided
Affected status: unknown
Allele origin:
germline
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Revvity Omics, Revvity
Accession: SCV002019642.3
First in ClinVar: Nov 29, 2021 Last updated: Feb 04, 2024 |
|
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Pathogenic
(Jan 25, 2023)
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criteria provided, single submitter
Method: clinical testing
|
not provided
Affected status: yes
Allele origin:
germline
|
Clinical Genetics Laboratory, Skane University Hospital Lund
Accession: SCV005198038.1
First in ClinVar: Aug 25, 2024 Last updated: Aug 25, 2024 |
|
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Pathogenic
(Mar 06, 2017)
|
criteria provided, single submitter
Method: clinical testing
|
Fetal akinesia deformation sequence 1
Congenital myasthenic syndrome 11
Affected status: unknown
Allele origin:
unknown
|
Counsyl
Accession: SCV000800750.1
First in ClinVar: Aug 04, 2018 Last updated: Aug 04, 2018 |
|
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Pathogenic
(Oct 17, 2017)
|
criteria provided, single submitter
Method: clinical testing
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Congenital myasthenic syndrome 11
Affected status: unknown
Allele origin:
germline
|
Illumina Laboratory Services, Illumina
Accession: SCV000372475.3
First in ClinVar: Dec 06, 2016 Last updated: May 24, 2019 |
Comment:
The RAPSN c.264C>A (p.Asn88Lys) variant is a well-documented pathogenic missense variant for congenital myasthenic syndrome (CMS). To date, all patients with CMS who carry a … (more)
The RAPSN c.264C>A (p.Asn88Lys) variant is a well-documented pathogenic missense variant for congenital myasthenic syndrome (CMS). To date, all patients with CMS who carry a variant in the RASPN gene carry the p.Asn88Lys variant on at least one allele (Richard et al. 2003). Across a selection of the available literature, the p.Asn88Lys variant is reported in 80 out of 216 patients, including in 31 homozygotes and 49 compound heterozygotes. The variant is also reported in three asymptomatic homozygous mothers of patients (Ohno et al. 2002; Burke et al. 2003; Muller et al. 2003; Richard et al. 2003; Maselli et al. 2003; Dunne et al. 2003; Muller et al. 2004; Skeie et al. 2006; Milone et al. 2009). The p.Asn88Lys variant was found in three of 720 total controls and is reported at a frequency of 0.00398 in the European population of the 1000 Genomes Project. Haplotype analysis suggests that the p.Asn88Lys variant may be derived from a single founder event in an ancient Indo-European population (Muller et al. 2004). The Asn88 residue is conserved (Ohno et al. 2002) and is located in a leucine zipper motif which is involved in acetylcholine receptor clustering (Dunne et al. 2003). Expression studies in HEK cells showed that the p.Asn88Lys variant significantly reduced the recruitment of the acetylcholine receptor to rapsyn clusters (Ohno et al. 2002). Based on the collective evidence, the p.Asn88Lys variant is classified as pathogenic for congenital myasthenic syndrome. This variant was observed by ICSL as part of a predisposition screen in an ostensibly healthy population. (less)
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Pathogenic
(Jun 21, 2019)
|
criteria provided, single submitter
Method: clinical testing
|
not provided
Affected status: unknown
Allele origin:
germline
|
Athena Diagnostics
Accession: SCV001145257.1
First in ClinVar: Jan 19, 2020 Last updated: Jan 19, 2020 |
Comment:
The best available variant frequency is more than 10 times the disease allele frequency, and is at least 0.1%. Statistically enriched in patients compared to … (more)
The best available variant frequency is more than 10 times the disease allele frequency, and is at least 0.1%. Statistically enriched in patients compared to ethnically matched controls. Found in at least one symptomatic patient. Predicted to have a damaging effect on the protein. Occurs in three or more cases with a recessive pathogenic variant in the same gene. Damaging to protein function(s) relevant to disease mechanism. Very strong co-segregation with disease in affected individuals from a single family. (less)
|
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Pathogenic
(-)
|
criteria provided, single submitter
Method: clinical testing
|
Congenital myasthenic syndrome 4C
Affected status: unknown
Allele origin:
germline
|
Baylor Genetics
Accession: SCV001163637.1
First in ClinVar: Feb 28, 2020 Last updated: Feb 28, 2020 |
|
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Pathogenic
(Aug 20, 2021)
|
criteria provided, single submitter
Method: clinical testing
|
Congenital myasthenic syndrome 11
Affected status: yes
Allele origin:
germline
|
Centogene AG - the Rare Disease Company
Accession: SCV002028340.1
First in ClinVar: Dec 04, 2021 Last updated: Dec 04, 2021 |
|
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Pathogenic
(Feb 01, 2022)
|
criteria provided, single submitter
Method: clinical testing
|
Congenital myasthenic syndrome
Affected status: unknown
Allele origin:
germline
|
Women's Health and Genetics/Laboratory Corporation of America, LabCorp
Accession: SCV002103767.1
First in ClinVar: Mar 12, 2022 Last updated: Mar 12, 2022 |
Comment:
Variant summary: RAPSN c.264C>A (p.Asn88Lys) results in a non-conservative amino acid change located in the Tetratricopeptide repeat (IPR019734) of the encoded protein sequence. Five of … (more)
Variant summary: RAPSN c.264C>A (p.Asn88Lys) results in a non-conservative amino acid change located in the Tetratricopeptide repeat (IPR019734) of the encoded protein sequence. Five of five in-silico tools predict a damaging effect of the variant on protein function. The variant allele was found at a frequency of 0.0016 in 250910 control chromosomes (gnomAD). This frequency is not higher than expected for a pathogenic variant in RAPSN causing Congenital Myasthenic Syndrome (0.0016 vs 0.0016). c.264C>A has been reported in the literature in multiple homozygous and compound heterozygous individuals affected with Congenital Myasthenic Syndrome and is considered a European founder mutation (e.g. Ohno_2002, Maselli_2003, Richard_2003, Cossins_2006, Abicht_2012). These data indicate that the variant is very likely to be associated with disease. Experimental evidence evaluating an impact on protein function demonstrated the variant affects the association of rapsyn with AChR and dramatically reduces the stability of AChR clusters (Ohno_2002, Cossins_2006). Sixteen ClinVar submitters (evaluation after 2014) cite the variant as pathogenic/likely pathogenic and one ClinVar submitter (evaluation after 2014) cites it as uncertain significance. Based on the evidence outlined above, the variant was classified as pathogenic. (less)
|
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Likely pathogenic
(Mar 05, 2018)
|
criteria provided, single submitter
Method: clinical testing
|
Congenital myasthenic syndrome 11
Affected status: yes
Allele origin:
inherited
|
Genomic Research Center, Shahid Beheshti University of Medical Sciences
Accession: SCV000784532.2
First in ClinVar: Oct 11, 2015 Last updated: Dec 11, 2022 |
Number of individuals with the variant: 1
Age: 0-9 years
Sex: female
Geographic origin: Iran
|
|
Likely pathogenic
(Mar 05, 2018)
|
criteria provided, single submitter
Method: clinical testing
|
Fetal akinesia deformation sequence 1
Affected status: yes
Allele origin:
inherited
|
Genomic Research Center, Shahid Beheshti University of Medical Sciences
Accession: SCV000784533.2
First in ClinVar: Dec 06, 2016 Last updated: Dec 11, 2022 |
Number of individuals with the variant: 1
Age: 0-9 years
Sex: female
Geographic origin: Iran
|
|
Pathogenic
(Feb 02, 2022)
|
criteria provided, single submitter
Method: clinical testing
|
Congenital myasthenic syndrome 11
(Autosomal recessive inheritance)
Affected status: yes
Allele origin:
germline
|
Victorian Clinical Genetics Services, Murdoch Childrens Research Institute
Additional submitter:
Shariant Australia, Australian Genomics
Accession: SCV002767266.1
First in ClinVar: Dec 24, 2022 Last updated: Dec 24, 2022 |
Comment:
Based on the classification scheme VCGS_Germline_v1.3.4, this variant is classified as Pathogenic. Following criteria are met: 0102 - Loss of function is a known mechanism … (more)
Based on the classification scheme VCGS_Germline_v1.3.4, this variant is classified as Pathogenic. Following criteria are met: 0102 - Loss of function is a known mechanism of disease in this gene and is associated with fetal akinesia deformation sequence 2 (MIM#618388) and congenital myasthenic syndrome 11 associated with acetylcholine receptor deficiency (MIM#616326). (I) 0106 - This gene is associated with autosomal recessive disease. (I) 0200 - Variant is predicted to result in a missense amino acid change from asparagine to lysine. (I) 0251 - This variant is heterozygous. (I) 0304 - Variant is present in gnomAD <0.01 for a recessive condition (v2: 429 heterozygotes, 0 homozygotes). (SP) 0502 - Missense variant with conflicting in silico predictions and uninformative conservation. (I) 0604 - Variant is not located in an established domain, motif, hotspot or informative constraint region. (I) 0801 - This variant has very strong previous evidence of pathogenicity in unrelated individuals. It is a well-known pathogenic variant, and it has been reported in multiple individuals with congenital myasthenic syndrome (ClinVar, PMID: 29054425). (SP) 1205 - This variant has been shown to be maternally inherited (by segregation analysis). (I) Legend: (SP) - Supporting pathogenic, (I) - Information, (SB) - Supporting benign (less)
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Pathogenic
(Nov 02, 2021)
|
criteria provided, single submitter
Method: clinical testing
|
Not Provided
Affected status: yes
Allele origin:
germline
|
GeneDx
Accession: SCV000329485.8
First in ClinVar: Dec 06, 2016 Last updated: Mar 04, 2023 |
Comment:
Published functional studies demonstrate a damaging effect, including diminished coclustering of AChR with rapsyn and impaired post-synaptic morphological development (Ohno et al., 2002; Cossins et … (more)
Published functional studies demonstrate a damaging effect, including diminished coclustering of AChR with rapsyn and impaired post-synaptic morphological development (Ohno et al., 2002; Cossins et al., 2006); In silico analysis, which includes protein predictors and evolutionary conservation, supports a deleterious effect; This variant is associated with the following publications: (PMID: 15328566, 12730725, 19620612, 25194721, 15482960, 11791205, 29053879, 16945936, 21228398, 12929188, 24319099, 20157724, 15286164, 26927095, 15036330, 12796535, 12807980, 17190963, 14659409, 21305573, 29189923, 29054425, 30266223, 30028532, 31226102, 27397848, 32070632, 31980526, 32403337, 31127727, 32528171) (less)
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Pathogenic
(Oct 10, 2022)
|
criteria provided, single submitter
Method: clinical testing
|
Congenital myasthenic syndrome 11
Affected status: yes
Allele origin:
germline
|
Laboratory of Medical Genetics, National & Kapodistrian University of Athens
Accession: SCV004013942.1
First in ClinVar: Jul 22, 2023 Last updated: Jul 22, 2023 |
Comment:
PS3, PM1, PM2, PP3, PP5
|
|
Pathogenic
(Jan 31, 2024)
|
criteria provided, single submitter
Method: clinical testing
|
Congenital myasthenic syndrome 11
Fetal akinesia deformation sequence 1
Explanation for multiple conditions: Uncertain.
The variant was classified for several related diseases, possibly a spectrum of disease; the variant may be associated with one or more the diseases.
Affected status: unknown
Allele origin:
germline
|
Labcorp Genetics (formerly Invitae), Labcorp
Accession: SCV000656543.9
First in ClinVar: Dec 26, 2017 Last updated: Feb 28, 2024 |
Comment:
This sequence change replaces asparagine, which is neutral and polar, with lysine, which is basic and polar, at codon 88 of the RAPSN protein (p.Asn88Lys). … (more)
This sequence change replaces asparagine, which is neutral and polar, with lysine, which is basic and polar, at codon 88 of the RAPSN protein (p.Asn88Lys). This variant is present in population databases (rs104894299, gnomAD 0.3%), and has an allele count higher than expected for a pathogenic variant. This missense change has been observed in individual(s) with congenital myasthenic syndrome (PMID: 12796535, 14504330, 16945936). In at least one individual the data is consistent with being in trans (on the opposite chromosome) from a pathogenic variant. It is commonly reported in individuals of European ancestry (PMID: 12796535, 14504330, 16945936). ClinVar contains an entry for this variant (Variation ID: 8046). Advanced modeling of protein sequence and biophysical properties (such as structural, functional, and spatial information, amino acid conservation, physicochemical variation, residue mobility, and thermodynamic stability) performed at Invitae indicates that this missense variant is not expected to disrupt RAPSN protein function with a negative predictive value of 80%. Experimental studies have shown that this missense change affects RAPSN function (PMID: 16945936). For these reasons, this variant has been classified as Pathogenic. (less)
|
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Pathogenic
(Dec 13, 2021)
|
criteria provided, single submitter
Method: clinical testing
|
Inborn genetic diseases
Affected status: unknown
Allele origin:
germline
|
Ambry Genetics
Accession: SCV003696773.2
First in ClinVar: Feb 07, 2023 Last updated: May 01, 2024 |
Comment:
The c.264C>A (p.N88K) alteration is located in exon 2 (coding exon 2) of the RAPSN gene. This alteration results from a C to A substitution … (more)
The c.264C>A (p.N88K) alteration is located in exon 2 (coding exon 2) of the RAPSN gene. This alteration results from a C to A substitution at nucleotide position 264, causing the asparagine (N) at amino acid position 88 to be replaced by a lysine (K). Based on data from gnomAD, the A allele has an overall frequency of 0.15% (429/282254) total alleles studied. The highest observed frequency was 0.26% (332/128732) of European (non-Finnish) alleles. This alteration is the most common mutation causing congenital myasthenic syndrome in Europeans. It has been reported in many affected homozygotes and heterozygotes with a second RAPSN alteration (Ohno, 2002; Abicht, 2003; Dunne, 2003; Maselli, 2003; Müller, 2003; Richard, 2003; Müller, 2004; Cossins, 2006; Milone, 2009). This amino acid position is highly conserved in available vertebrate species. Functional studies demonstrated that the p.N88K alteration resulted in significantly reduced co-localization with the acetylcholine receptor (Ohno, 2002; Cossins, 2006). This alteration is predicted to be tolerated by in silico analysis. Based on the available evidence, this alteration is classified as pathogenic. (less)
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Pathogenic
(Mar 30, 2024)
|
criteria provided, single submitter
Method: clinical testing
|
Fetal akinesia deformation sequence 2
Affected status: unknown
Allele origin:
unknown
|
Baylor Genetics
Accession: SCV004206077.2
First in ClinVar: Dec 30, 2023 Last updated: Jun 17, 2024 |
|
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Pathogenic
(Feb 01, 2024)
|
criteria provided, single submitter
Method: clinical testing
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not provided
Affected status: yes
Allele origin:
germline
|
CeGaT Center for Human Genetics Tuebingen
Accession: SCV001245792.26
First in ClinVar: May 09, 2020 Last updated: Oct 20, 2024 |
Comment:
RAPSN: PM3:Very Strong, PM2:Supporting, PP1, PS3:Supporting
Number of individuals with the variant: 8
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Pathogenic
(Dec 08, 2023)
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criteria provided, single submitter
Method: clinical testing
|
Not provided
Affected status: unknown
Allele origin:
germline
|
Mayo Clinic Laboratories, Mayo Clinic
Accession: SCV005413988.1
First in ClinVar: Nov 24, 2024 Last updated: Nov 24, 2024 |
Comment:
PM3, PS3, PS4
Number of individuals with the variant: 1
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Pathogenic
(Dec 26, 2006)
|
no assertion criteria provided
Method: literature only
|
MYASTHENIC SYNDROME, CONGENITAL, 11, ASSOCIATED WITH ACETYLCHOLINE RECEPTOR DEFICIENCY
Affected status: not provided
Allele origin:
germline
|
OMIM
Accession: SCV000028720.2
First in ClinVar: Apr 04, 2013 Last updated: Apr 30, 2015 |
Comment on evidence:
In 2 patients with congenital myasthenic syndrome-11 (CMS11; 616326) associated with AChR deficiency, Ohno et al. (2002) identified a homozygous asn88-to-lys (N88K) mutation in the … (more)
In 2 patients with congenital myasthenic syndrome-11 (CMS11; 616326) associated with AChR deficiency, Ohno et al. (2002) identified a homozygous asn88-to-lys (N88K) mutation in the RAPSN gene. The N88K mutation was identified in the compound heterozygous state with leu14-to-pro (L14P; 601592.0002) in one patient and with 553ins5 (601592.0003) in another. The N88K substitution results from a 264C-A transversion in exon 2 of the RAPSN gene (Muller et al., 2004). Dunne and Maselli (2003) identified the N88K mutation in each of 4 patients from 4 different families with CMS and AChR deficiency. One patient was homozygous for N88K and was only mildly affected, whereas the other 3 patients were heterozygous for N88K and a second mutation (L14P; 601592.0002), (46insC; 601592.0004), or (Y269X; 601592.0005) and were severely affected. The authors noted that the N88K mutation occurs within the putative leucine zipper motif, which is important for clustering of the acetylcholine receptor. Among 120 CMS patients from 110 unrelated families, Muller et al. (2003) identified the N88K mutation in 12 patients (10%) from 10 families. Seven patients were homozygous for the mutation and 5 patients were compound heterozygous. Genotype analysis of the region of chromosome 11 close to the RAPSN gene suggested that the N88K allele derived from a common European ancestor. Burke et al. (2003) reported 16 patients with CMS caused by the N88K mutation: 7 were homozygous and 9 were compound heterozygous. By haplotype analysis of 21 CMS patients of European and Indian origin with the N88K mutation, Muller et al. (2004) identified a core founder haplotype of 10 SNPs encompassing a region of 0.36 Mb flanking the mutation and concluded that N88K derived from a single founder event in an ancient Indo-European population. Skeie et al. (2006) reported a boy with an unusually mild CMS phenotype who was homozygous for the N88K mutation. Until age 5 years, he had repeated episodes of weakness with respiratory insufficiency and swallowing difficulties associated with febrile illnesses. By age 19, he participated in normal physical activity, experiencing only occasional muscle cramps and ptosis. He was always symptom-free between attacks and had normal serologic tests, normal acetylcholine receptor levels, no decrement on repetitive muscle stimulation, and no response to acetylcholinesterase inhibitors. The findings expanded the phenotype associated with the N88K mutation. (less)
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Pathogenic
(Jan 26, 2016)
|
no assertion criteria provided
Method: research
|
Congenital myasthenic syndrome 11
Fetal akinesia deformation sequence 1
Affected status: unknown
Allele origin:
germline
|
Division of Human Genetics, Children's Hospital of Philadelphia
Study: CSER-PediSeq
Accession: SCV000536719.1 First in ClinVar: Apr 23, 2017 Last updated: Apr 23, 2017 |
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Pathogenic
(Sep 16, 2020)
|
no assertion criteria provided
Method: clinical testing
|
Congenital myasthenic syndrome
Affected status: unknown
Allele origin:
germline
|
Natera, Inc.
Accession: SCV001460221.1
First in ClinVar: Jan 02, 2021 Last updated: Jan 02, 2021 |
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Pathogenic
(-)
|
no assertion criteria provided
Method: clinical testing
|
not provided
Affected status: yes
Allele origin:
germline
|
Laboratory of Diagnostic Genome Analysis, Leiden University Medical Center (LUMC)
Study: VKGL Data-share Consensus
Accession: SCV001800686.1 First in ClinVar: Aug 21, 2021 Last updated: Aug 21, 2021 |
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Pathogenic
(-)
|
no assertion criteria provided
Method: clinical testing
|
not provided
Affected status: yes
Allele origin:
germline
|
Genome Diagnostics Laboratory, Amsterdam University Medical Center
Study: VKGL Data-share Consensus
Accession: SCV001808376.1 First in ClinVar: Aug 27, 2021 Last updated: Aug 27, 2021 |
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Pathogenic
(-)
|
no assertion criteria provided
Method: clinical testing
|
not provided
Affected status: yes
Allele origin:
germline
|
Clinical Genetics DNA and cytogenetics Diagnostics Lab, Erasmus MC, Erasmus Medical Center
Additional submitter:
Diagnostic Laboratory, Department of Genetics, University Medical Center Groningen
Study: VKGL Data-share Consensus
Accession: SCV001976320.1 First in ClinVar: Oct 08, 2021 Last updated: Oct 08, 2021 |
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Pathogenic
(Jun 21, 2024)
|
no assertion criteria provided
Method: clinical testing
|
RAPSN-related condition
Affected status: unknown
Allele origin:
germline
|
PreventionGenetics, part of Exact Sciences
Accession: SCV005364025.1
First in ClinVar: Oct 08, 2024 Last updated: Oct 08, 2024 |
Comment:
The RAPSN c.264C>A variant is predicted to result in the amino acid substitution p.Asn88Lys. This variant has been reported, in the compound heterozygous or homozygous … (more)
The RAPSN c.264C>A variant is predicted to result in the amino acid substitution p.Asn88Lys. This variant has been reported, in the compound heterozygous or homozygous state, as a recurrent RAPSN variant in many individuals with autosomal recessive congenital myasthenic syndrome (Ohno et al. 2002. PubMed ID: 11791205; Ohno et al. 2004. PubMed ID: 14729848; Brugnoni et al. 2010. PubMed ID: 20157724; Laquérriere. 2014. PubMed ID: 24319099; Natera-de Benito. 2017. PubMed ID: 29054425; McMacken. 2018. PubMed ID: 29189923). Functional studies suggest that the p.Asn88Lys variant results in reduced stability of the AChR clusters (Cossins. 2006. PubMed ID: 16945936). This variant is reported in 0.26% of alleles in individuals of European (Non-Finnish) descent in gnomAD. This variant is interpreted as pathogenic. (less)
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Pathogenic
(Oct 19, 2023)
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no assertion criteria provided
Method: clinical testing
|
Congenital myasthenic syndrome 11
Affected status: yes
Allele origin:
maternal
|
Undiagnosed Diseases Network, NIH
Study: Undiagnosed Diseases Network (NIH), UDN
Accession: SCV005368706.1 First in ClinVar: Oct 13, 2024 Last updated: Oct 13, 2024 |
Number of individuals with the variant: 1
Clinical Features:
Open mouth (present) , High palate (present) , Micrognathia (present) , Low-set ears (present) , Ptosis (present) , Neonatal hypotonia (present) , Joint hypermobility (present) … (more)
Open mouth (present) , High palate (present) , Micrognathia (present) , Low-set ears (present) , Ptosis (present) , Neonatal hypotonia (present) , Joint hypermobility (present) , Pes planus (present) , Myalgia (present) , Prominent forehead (present) , Thin corpus callosum (present) , Long fingers (present) , Bilateral facial palsy (present) (less)
Age: 0-9 years
Sex: male
Tissue: Blood
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Pathogenic
(-)
|
no assertion criteria provided
Method: clinical testing
|
not provided
Affected status: yes
Allele origin:
germline
|
Diagnostic Laboratory, Department of Genetics, University Medical Center Groningen
Study: VKGL Data-share Consensus
Accession: SCV001741814.3 First in ClinVar: Jul 07, 2021 Last updated: Sep 08, 2021 |
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Pathogenic
(-)
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no assertion criteria provided
Method: clinical testing
|
not provided
Affected status: yes
Allele origin:
germline
|
Joint Genome Diagnostic Labs from Nijmegen and Maastricht, Radboudumc and MUMC+
Additional submitter:
Diagnostic Laboratory, Department of Genetics, University Medical Center Groningen
Study: VKGL Data-share Consensus
Accession: SCV001955749.1 First in ClinVar: Oct 02, 2021 Last updated: Oct 02, 2021 |
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not provided
(-)
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no classification provided
Method: literature only
|
Congenital myasthenic syndrome
Affected status: yes
Allele origin:
germline
|
GeneReviews
Accession: SCV000292404.2
First in ClinVar: Jul 19, 2016 Last updated: Oct 01, 2022 |
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Germline Functional Evidence
There is no functional evidence in ClinVar for this variation. If you have generated functional data for this variation, please consider submitting that data to ClinVar. |
Citations for germline classification of this variant
HelpTitle | Author | Journal | Year | Link |
---|---|---|---|---|
Congenital Myasthenic Syndromes Overview. | Adam MP | - | 2021 | PMID: 20301347 |
Clinical variability of early-onset congenital myasthenic syndrome due to biallelic RAPSN mutations in Brazil. | Estephan EP | Neuromuscular disorders : NMD | 2018 | PMID: 30266223 |
Congenital Myasthenic Syndrome: Spectrum of Mutations in an Indian Cohort. | Selvam P | Journal of clinical neuromuscular disease | 2018 | PMID: 30124556 |
Congenital myasthenic syndrome with episodic apnoea: clinical, neurophysiological and genetic features in the long-term follow-up of 19 patients. | McMacken G | Journal of neurology | 2018 | PMID: 29189923 |
Decrement with high frequency repetitive nerve stimulation in a RAPSN congenital myasthenic syndrome. | LoRusso SJ | Muscle & nerve | 2018 | PMID: 29053879 |
Molecular characterization of congenital myasthenic syndromes in Spain. | Natera-de Benito D | Neuromuscular disorders : NMD | 2017 | PMID: 29054425 |
Potentially Treatable Disorder Diagnosed Post Mortem by Exome Analysis in a Boy with Respiratory Distress. | Imperatore V | International journal of molecular sciences | 2016 | PMID: 26927095 |
Late presentations of congenital myasthenic syndromes: How many do we miss? | Garg N | Muscle & nerve | 2016 | PMID: 26910802 |
Long-term follow-up in patients with congenital myasthenic syndrome due to RAPSN mutations. | Natera-de Benito D | Neuromuscular disorders : NMD | 2016 | PMID: 26782015 |
Congenital myasthenic syndrome in Japan: ethnically unique mutations in muscle nicotinic acetylcholine receptor subunits. | Azuma Y | Neuromuscular disorders : NMD | 2015 | PMID: 25264167 |
Use of next-generation sequencing as a diagnostic tool for congenital myasthenic syndrome. | Das AS | Pediatric neurology | 2014 | PMID: 25194721 |
Mutations in CNTNAP1 and ADCY6 are responsible for severe arthrogryposis multiplex congenita with axoglial defects. | Laquérriere A | Human molecular genetics | 2014 | PMID: 24319099 |
Congenital myasthenic syndromes: achievements and limitations of phenotype-guided gene-after-gene sequencing in diagnostic practice: a study of 680 patients. | Abicht A | Human mutation | 2012 | PMID: 22678886 |
Investigation for RAPSN and DOK-7 mutations in a cohort of seronegative myasthenia gravis patients. | Alseth EH | Muscle & nerve | 2011 | PMID: 21305573 |
Carrier testing for severe childhood recessive diseases by next-generation sequencing. | Bell CJ | Science translational medicine | 2011 | PMID: 21228398 |
Multiexon deletions account for 15% of congenital myasthenic syndromes with RAPSN mutations after negative DNA sequencing. | Gaudon K | Journal of medical genetics | 2010 | PMID: 20930056 |
Molecular characterisation of congenital myasthenic syndromes in Southern Brazil. | Mihaylova V | Journal of neurology, neurosurgery, and psychiatry | 2010 | PMID: 20562457 |
Identification of previously unreported mutations in CHRNA1, CHRNE and RAPSN genes in three unrelated Italian patients with congenital myasthenic syndromes. | Brugnoni R | Journal of neurology | 2010 | PMID: 20157724 |
Myasthenic syndrome due to defects in rapsyn: Clinical and molecular findings in 39 patients. | Milone M | Neurology | 2009 | PMID: 19620612 |
Unusual features in a boy with the rapsyn N88K mutation. | Skeie GO | Neurology | 2006 | PMID: 17190963 |
Diverse molecular mechanisms involved in AChR deficiency due to rapsyn mutations. | Cossins J | Brain : a journal of neurology | 2006 | PMID: 16945936 |
A newly identified chromosomal microdeletion of the rapsyn gene causes a congenital myasthenic syndrome. | Müller JS | Neuromuscular disorders : NMD | 2004 | PMID: 15482960 |
Congenital myasthenic syndrome due to rapsyn deficiency: three cases with arthrogryposis and bulbar symptoms. | Ioos C | Neuropediatrics | 2004 | PMID: 15328566 |
The congenital myasthenic syndrome mutation RAPSN N88K derives from an ancient Indo-European founder. | Müller JS | Journal of medical genetics | 2004 | PMID: 15286164 |
Novel truncating RAPSN mutations causing congenital myasthenic syndrome responsive to 3,4-diaminopyridine. | Banwell BL | Neuromuscular disorders : NMD | 2004 | PMID: 15036330 |
Lack of founder haplotype for the rapsyn N88K mutation: N88K is an ancient founder mutation or arises from multiple founders. | Ohno K | Journal of medical genetics | 2004 | PMID: 14729848 |
Electrophysiological and morphological characterization of a case of autosomal recessive congenital myasthenic syndrome with acetylcholine receptor deficiency due to a N88K rapsyn homozygous mutation. | Yasaki E | Neuromuscular disorders : NMD | 2004 | PMID: 14659409 |
Rapsyn mutations in hereditary myasthenia: distinct early- and late-onset phenotypes. | Burke G | Neurology | 2003 | PMID: 14504330 |
Rapsyn mutations in myasthenic syndrome due to impaired receptor clustering. | Maselli RA | Muscle & nerve | 2003 | PMID: 12929188 |
Possible founder effect of rapsyn N88K mutation and identification of novel rapsyn mutations in congenital myasthenic syndromes. | Richard P | Journal of medical genetics | 2003 | PMID: 12807980 |
Rapsyn N88K is a frequent cause of congenital myasthenic syndromes in European patients. | Müller JS | Neurology | 2003 | PMID: 12796535 |
Identification of pathogenic mutations in the human rapsyn gene. | Dunne V | Journal of human genetics | 2003 | PMID: 12730725 |
E-box mutations in the RAPSN promoter region in eight cases with congenital myasthenic syndrome. | Ohno K | Human molecular genetics | 2003 | PMID: 12651869 |
Rapsyn mutations in humans cause endplate acetylcholine-receptor deficiency and myasthenic syndrome. | Ohno K | American journal of human genetics | 2002 | PMID: 11791205 |
http://www.egl-eurofins.com/emvclass/emvclass.php?approved_symbol=RAPSN | - | - | - | - |
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Text-mined citations for rs104894299 ...
HelpRecord last updated Nov 25, 2024
This date represents the last time this VCV record was updated. The update may be due to an update to one of the included submitted records (SCVs), or due to an update that ClinVar made to the variant such as adding HGVS expressions or a rs number. So this date may be different from the date of the “most recent submission” reported at the top of this page.